International Journal of Renewable Energy Research-IJRER

The biofuel products from halophyte plants are valuable due to their high oil content and growth on non-productive, salt-affected lands. The northern part of Golestan province has high potential for biofuel production from salt-tolerant plants such as Salicornia Bigelovii (oilseed halophyte) due to its water and soil properties. In this paper, the suitable locations for growing of Salicornia plant in Golestan province were defined based on environmental suitability analysis. By this analysis the suitable area for cultivation and total amount of producible biodiesel were evaluated. In this regard, the principal parameters were defined then the suitable areas were specified by spatial superposition of these layers, using Geographical Information System (GIS). Index Overlay model was applied for maps combination in environmental suitability analysis. The results demonstrate that the most suitable lands for growing Salicornia are located in the north-west part of Golestan province with an area of 2365 Km² corresponding to around %12 of total study area. Total amount of producible biodiesel of this area is estimated to 201.143 million liters per year.

Bioenergy, Biofuel, Site selection, GIS, Salicornia

S. H. Yokoyama, Y. Matsumura, The Asian biomass handbook. The japan institute of energy,2008.

S. Hull, Wisconsin Sustainable Planting and Harvesting Guidelines for Nonforest Biomass. Wisconsin Bioenergy Council , 2011.

E. M. Nada, The Manufacture of Biodiesel from the used vegetable oil. Thesis submitted to the Faculty of Engineering at Kassel and Cairo Universities, 2001.

Haas Center, An Evaluation of Biodiesel Production Feasibility in Santa Rosa County. Haas Center for Business Research and Economic Development, 2005.

J. Crockett, C.L. Peterson, P. Mann, Feasibility Study for Commercial Production of Biodiesel in the Treasure Valley of Idaho. Universityof Idaho,College of Biological & Agricultural Engineering, 2006.

R. M. Garcia, Physiological studies of the halophyte Salicornia bigelovii:A potential food and biofule crop for integrated

aquaculture- agriculture systems.The university of Arizona, 2010.

E. P. Glenn, J.J. Brown, Salt Tolerance and Crop Potential of Halophytes. Critical Reviews in Plant Sciences, 1999. 18(2): 227–255.

A. Thomas, A. Bond, K. Hiscock, A GIS based assessment of bioenergy potential in England within existing energy systems. Biomass and Bioenergy, 2013; 55: 107–121.

D. Voivontas, D. Assimacopoulos, E.G. Koukios. Aessessment of biomass potential for power production: a GIS based method. Biomass and Bioenergy, 2001; 20(2):101–112.

E. Schreurs, T. Voets. T. Thewys, GIS-based assessment of the biomass potential from phytoremediation of contaminated agricultural land in the Campine region in Belgium. Biomass and Bioenergy, 2011; 35(10): 4469–4480.

T. Voets, A. Neven, T. Thewys, T. Kuppens, GIS-based location optimization of a biomass conversion plant on contaminated willow in the Campine region (Belgium). Biomass and Bioenergy, 2013; 55: 339–349.

M. A. Haddad, P.F. Anderson, A GIS methodology to identify potential corn stover collection locations. Biomass and Bioenergy, 2008; 32 (12):1097–1108.

Y. Noorollahi., R. Itoi, H. Fujii, T. Toshiaki, GIS integration model for geothermal exploration and well siting. Geothermics, 2008; 37( 2): 107-131.

Y. Noorollahi, R. Itoi, H. Fujii, T. Toshiaki, GIS model for geothermal resource exploration in Akita and Iwate prefectures, Northern Japan. Journal of Computer & Geosciences, 2006; 33( 8): 1008-1021.

J. Höhn, E. Lehtonen, S. Rasi, J. Rintala, A Geographical Information System (GIS) based methodology for determination of potential biomasses and sites for biogas plants in southern Finland. Applied Energy, 2014; 113: 1–10.

S. L. Falasca, A. Ulberich, A. Acevedo, Identification of Argentinian saline drylands suitable for growing Salicornia bigelovii for bioenergy. International Journal of Hydrogen Energy, 2014; 39 (16): 8682–8689.

D. K. Sidiras, GIS based simulation of the biodiesel penetration in European Union markets: The case of Greece. Biomass and Bioenergy, 21st European Biomass Conference, 2014, 65: 101–111.

B. Niblick, J.D. Monnell, X. Zhao, A.E. Landis, Using geographic information systems to assess potential biofuel crop production on urban marginal lands. Applied Energy, 2013; 103 : 234–242.

M. Hiloidhari, D. Baruah, H. Mahilary, D.C. Baruah, GIS based assessment of rice (Oryza sativa) straw biomass as an alternative fuel for tea (Camellia sinensis L.) drying in Sonitpur district of Assam, India. Biomass and Bioenergy, 2012, 44: 160–167.

F. Zhang, D.M. Johnson, J.W. Sutherland, A GIS-based method for identifying the optimal location for a facility to convert forest biomass to biofuel. Biomass and Bioenergy, 2011; 35(9): 3951–3961.

M. Beccali, P. Columba, V. D’Alberti, V. Franzitta, Assessment of bioenergy potential in Sicily: A GIS-based support methodology, Biomass and Bioenergy, 2009; 33(1) : 79–87.

M. Arab Khedri, D. Nik Kami, E. Farahani, Investigating the application of Salicornia species in forage and oil production. International Information System for the Agricultural science and technology, 2008.

E. Kohan Baghikhtarani, A. Abdolzadeh, M.B. Bagherieh, Feasibility study of the biodiesel production from salt tolerance of province Golestan. The first stable development of National Congress, Green Fuel, Esfahan, 2013.

H. Sharifan, S. Alaghmand, Zoning of the 10-Days, Monthly and Annual Rainfall Using GIS: A Case Study on Golestan Province. Iran Published in: Map Asia, 2007.

http://www.gsrw.ir. Available on 20/2/2014.

A. J. Davy, G.F. Bishop, C.S.B. Costa, Salicornia L.( Salicornia pusilla J. Woods, S. ramosissima J. Woods, S. europaea L., S. obscura P.W. Ball & Tutin, S. nitens P.W. Ball & Tutin, S. fragilis P.W. Ball & Tutin and S. dolichostachya Moss). Journal of Ecology, 2001; 89: 681–707.

E. P. Glenn and et.al., Three halophytes for saline-water agriculture: An oilseed, a forage and a grain crop. Environmental and Experimental Botany, 2013; 92: 110–121.

E. Omar Rueda-Puente, Ameliorative effects of salt resistance on physiological parameters in the halophyte Salicornia bigelovii torr. with plant growth-promoting rhizobacteria. African Journal of Biotechnology, 2013; 12(34): 5278-5284.

Y. Bashan, M. Moreno, E. Troyo, Growth promotion of the seawater-irrigated oilseed halophyte Salicornia bigelovii inoculated with mangrove rhizosphere bacteria and halotolerant Azospirillum spp. Journal of Ecology, 2000; 32: 265-272.

E. Omar Rueda-Puente, Bacterial Community of Rhizosphere Associated to the Annual Halophte Salicornia bigelovii (Torr.). Terra Latinoamericana, 2010; 28( 4): 345-353.

R. C. Christiansen, Sea asparagus can be oilseed feedstock for biodiesel. Biomass Magazine, 2008.

C. Perpinaa, J.C. Martinez-Llariob, A.P. Navarroa, Multicriteria assessment in GIS environments for siting biomass plants. Land Use Policy, 2013;31: 326– 335.

Bonham-Carter, G.F., 1994. Geographical Information Systems for Geoscientists: Modeling with GIS. Computer Methods in the Geosciences, vol. 13. Pergamon, New York, NY, USA, 398 pp.

J. Scianna, The United States Department of Agriculture, 2002.

M. F. Makhdoom, Fundamental of Landuse Planning, 10th edition, University of Tehran Press (in Persian), 2010.